Connector with a dual diaphragm valve

ABSTRACT

Positive displacement using a connector with dual diaphragms is provided. For example, the connector includes a single fluid flow path, an air chamber and a valve. The single fluid flow path is configured for delivering fluid to a person and configured for receiving fluid from a person. The air chamber configured for expelling air from the air chamber when an actuator is inserted into the connector and for receiving air into the chamber when the actuator is removed from the connector. The valve plug comprises two diaphragms that separate the air chamber from the single fluid flow path. The valve plug is configured for creating positive displacement by returning the valve plug to its uncompressed state when the actuator is removed from the connector.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.14/728,870, filed Jun. 2, 2015, entitled “PROVIDING POSITIVEDISPLACEMENT UPON DISCONNECTION USING A CONNECTOR WITH A DUAL DIAPHRAGMVALVE,” which is a continuation of U.S. patent application Ser. No.13/190,346, filed Jul. 25, 2011, issued as U.S. Pat. No. 9,067,049, andentitled “PROVIDING POSITIVE DISPLACEMENT UPON DISCONNECTION USING ACONNECTOR WITH A DUAL DIAPHRAGM VALVE,” the disclosure of each of whichis incorporated herein by reference in its entirety for all purposes.

BACKGROUND

The present technology relates generally to medical connectors. Moreparticularly, the present technology relates to providing positivedisplacement upon disconnection of an actuator from a connector by usinga connector with a dual diaphragm valve.

Medical connectors are widely used for delivering fluid to a patient orfor drawing fluid from a patient. Examples of delivered fluid include,but are not limited to, medication, intravenous fluid and enteralfeeding fluid. Examples of fluids that are drawn from a patient includeblood and bodily fluids.

The use of hypodermic needles has been gradually decreasing due to therisks of infection and cost considerations, among other things.Hypodermic needles are being replaced with needless connectors that usean actuator, instead of a needle. The needless connector can placed, forexample, at one end of a catheter while the other end of the catheter isconnected to a patient. The actuator can be inserted into an end of theneedless connector.

BRIEF DESCRIPTION OF THE DRAWINGS

Various features of illustrative embodiments of the inventions aredescribed below with reference to the drawings. The illustratedembodiments are intended to illustrate, but not to limit, theinventions. The drawings contain the following figures:

FIG. 1A depicts a side cross section of a connector that is unaccessed,according to one embodiment.

FIG. 1B depicts a side cross section of a connector that is accessed,according to one embodiment.

FIG. 1C depicts a side cross section of a connector upon disconnection,according to one embodiment.

FIG. 2A depicts a housing, according to one embodiment.

FIG. 2B depicts a side cross section of a valve plug, according to oneembodiment.

FIG. 2C depicts a base, according to one embodiment.

FIG. 2D depicts an insert, according to one embodiment.

FIG. 3 depicts a side cross section of a partially assembled connector,according to one embodiment.

FIG. 4 depicts a top cross section view of the outline of an assembledconnector, according to one embodiment.

FIG. 5 depicts a side cross section view of an empty assembled connectorfrom cross section, which runs at least through one rib, according toone embodiment.

FIG. 6 depicts a side cross section view of an assembled connectorcontaining fluid from cross section, which runs through at least onerib, according to one embodiment.

FIG. 7 depicts a side cross section view of an actuated connector,according to one embodiment.

FIGS. 8A and 8B depict a flowchart of a method for making a connector,according to one embodiment.

FIG. 9 is a flow chart for a method of making a connector, according toanother embodiment.

The drawings referred to in this description should not be understood asbeing drawn to scale unless specifically noted.

DETAILED DESCRIPTION

In the following detailed description, numerous specific details are setforth to provide a full understanding of the subject technology. Itshould be understood that the subject technology may be practicedwithout some of these specific details. In other instances, well-knownstructures and techniques have not been shown in detail so as not toobscure the subject technology. The detailed description will begin withan overview followed by a detailed description of various embodimentsfor providing a connector with a dual diaphragm valve.

Connectors that involve one or more moving parts can result indisplacement of fluid. Displacement can be positive or negative. Thephrase “positive displacement,” refers to fluid being pushed out of theconnector into the catheter and possibly then being pushed into thepatient. The phrase “negative displacement,” refers to fluid beingpulled from the patient into the catheter and possibly then being pulledinto the connector. Displacement can occur when an actuator is insertedinto a connector or when an actuator is removed from a connector.

The terms “accessed,” and ‘actuated,” shall be used to refer to thestate of the connector when an actuator is inserted into the connector.The terms “unaccessed,” and “unactuated,” shall be used to refer to thestate of the connector when an actuator is not inserted into theconnector. The term “disconnection,” shall be used to refer to the actof removing the actuator from the connector.

One of the problems with negative displacement upon disconnection is ifbody fluids are pulled into the connector, the body fluids can coagulatepotentially resulting in an obstructed connector, An obstructedconnector may need to be replaced with a new connector.

Therefore, according to one embodiment, positive displacement isprovided upon disconnection. Since positive displacement pushes fluidsout of the connector, positive displacement prevents body fluids frombeing pulled into the connector, and thus, prevents obstruction due tocoagulation of body fluids.

In contrast, one of the problems with positive displacement upondisconnection is that the displaced medication can be pushed into thepatient potentially resulting in an overdose.

According to one embodiment, minimal positive displacement is provided.Minimal displacement prevents potential drug overdoses since anegligible amount of medication is pushed out, as will become moreevident.

FIGS. 1A-1C depict side cross section views of a connector 100 in greyscale, according to various embodiments, where the housing is thedarkest shade of grey, the valve plug and the base are in anintermediate shade of grey, and the insert is in the lightest shade ofgrey.

FIG. 1A depicts a side cross section view of a connector 100 that isunaccessed, according to one embodiment. The connector 100 includes afluid flow path (FFP) 112, an air chamber 110, a housing 108, a valveplug 104 with two diaphragms 116, 118, and vent holes 120, 122, amongother things. The fluid flow path 112 is depicted with lines that movefrom the upper right corner down to the lower left corner and the airchamber 110 is depicted with cross hatchings, according to oneembodiment. The fluid flow path 112 is sealed at the top 102 of theconnector 100 and at the shoulder 114 of the valve plug 104 where thevalve plug 104 contacts the housing 108.

FIG. 1B depicts a side cross section view of a connector 100 that isaccessed, according to one embodiment. The fluid flow path 112 isdepicted with lines that move from the upper right corner down to thelower left corner and the air chamber 110 is depicted with crosshatchings, according to one embodiment. According to variousembodiments, displacement is provided by the change in the volumesassociated respectively with the fluid flow path 112 and the air chamber110. For example, the inserted actuator 124 pushes the valve plug 104downwards causing the valve plug and the associated diaphragms 116, 118to move downwards. This is also referred to as deforming or compressingthe valve plug 104 upon actuation. The volume associated with the fluidflow path 112 enlarges. Further, air is pushed out of the air chamber110 through the vent holes 120, 122 and the volume associated with theair chamber 110 reduces in size. The seal at the top 102 and at theshoulder 114 are opened by the deformation of the valve plug 104,opening the fluid flow path 112 for fluid to flow between the actuator124 and the bottom port 126. Negative displacement 128 occurs withfluid, such as bodily fluids, being pulled into the catheter andpossibly into the connector 100. However, the medication then starts toflow from the actuator 124, through the fluid flow path 112, out thebottom port 126, through the catheter and to the patient, thus, ifbodily fluids were pulled into the connector 100, they will not remainin the catheter upon actuation for the purposes of delivering fluids tothe patient.

In contrast, FIG. 10 depicts a side cross section view of a connector100 upon disconnection, according to one embodiment. The fluid flow path112 is depicted with lines that move from the upper right corner down tothe lower left corner and the air chamber 110 is depicted with crosshatchings, according to one embodiment. According to variousembodiments, upon disconnection, the valve plug 104 returns to anundeformed uncompressed state when the actuator 124 is removed. Thefluid flow path 112 and the air chamber 110 resume the same orapproximately the same shape and volume that they had before they wereaccessed as depicted in FIG. 1A. The seals at the top 102 and at theshoulder 114 return. The diaphragms 116, 118 move upwards causing thefluid flow path 112's volume to reduce in size and the air chamber 110'svolume to increase in size as air is pulled into the air chamber 110'svolume through the vent holes 120, 122. Positive displacement 132 occurswith fluid, such as medication or bodily fluids, being pushed out thebottom port 126, into the catheter and possibly into the patient.

Therefore, according to one embodiment, it is the changes in therespective volumes of the fluid flow path and the air chamber due atleast in part to the movement of the diaphragms 116, 118 that providefor positive displacement upon disconnection and negative displacementupon actuation, as discussed herein.

A connector as depicted in FIGS. 1A-1C includes various components,according to one embodiment. FIGS. 2A-2D depict components of aconnector 100, according to one embodiment.

FIG. 2A depicts a housing 210, according to one embodiment. For example,the housing 210 as depicted includes a top 212, a top port 211, maleluer threads 213, an upper valve chamber 214, a housing to insertinterface 215, an insert chamber 216, and a housing to base interface217, according to one embodiment. The top port 211 is configured so thatan actuator can be inserted into it, According to one embodiment, thetop port 211 is configured so that an inserted actuator fits snugly inthe top port 211. The male luer threads 213 can be used for screwing acap associated with the actuator securely to the connector. The housingto insert interface 215 is used for connecting the housing 210 and aninsert. The insert chamber 216 provides a volume for a portion of theinsert to reside when the insert is placed inside of the housing 210.The housing to base interface 217 is used for connecting the housing 210and a base. The housing 210 can include one or more ribs. The ribs areon the outside of the housing 210, according to one embodiment.According to one embodiment, at least one of the ribs is configured toprovide a portion of a fluid flow path, as will become more evident.

FIG. 2B depicts a side cross section view of a valve plug 220, accordingto one embodiment. For example, the valve plug 220 as depicted includesa top 290, a throat 222, a semi-circular notch 221 on one side of thevalve plug 220, a shoulder 224, a top diaphragm 226 a, a bottomdiaphragm 226 b, skirts 225 a, 225 b of the respective diaphragms 226 a,226 b, expansions 227 a, 227 b of the respective diaphragms 226 a, 226b, a tail 229 between the two diaphragms 226 a, 226 b, and two curves228 a, 228 b in the tail 229. The two diaphragms 226 a, 226 b are alsoreferred to as a “dual diaphragm.” According to one embodiment, thebottom diaphragm 226 b has a smaller diameter than the top diaphragm 226a The top diaphragm 226 a' s skirt 225 a is oriented downwards, Thebottom diaphragm 226 b's skirt 225 b is oriented horizontally. Eitherone or both of the skirts 225 a, 225 b can be oriented downwards,upwards, or horizontally, among other things, according to variousembodiments. The diaphragms 226 a, 226 b include expansions 227 a, 227b, according to one embodiment, oriented, for example, at the edges ofthe diaphragms 226 a, 226 b. The respective expansions 227 a, 227 b canbe used, for example, as a part of holding the diaphragms 226 a, 226 bin place when assembled with the other connector components. Asdepicted, the tail 229 includes two curves 228. Although the tail 229 isdepicted with two curves 228 a, 228 b, fewer or additional curves may beused.

According to one embodiment, the valve plug 220 is made of a singlepiece of material. According to one embodiment, the valve plug 220 ismade of a solid piece of material. According to one embodiment,injection molded silicon can be used to make a valve plug 220 that is asingle solid piece. According to one embodiment, the valve plug 220 maybe a single piece of material that is hollow inside or contains an airpocket inside of it. According to one embodiment, the valve plug 220does not require a septum or a channel that flows through it. Forexample, as will become more evident, a fluid flow path runs around thevalve plug 220, according to one embodiment, instead of through thevalve plug 220. According to another embodiment, the valve plug 220 mayinclude more than one piece that interacts with each other.

FIG. 2C depicts a base 240, according to one embodiment. For example,the base 240 as depicted includes a vent hole 241, an insert to baseinterface 242, female threads 243, a housing to base interface 245, anda bottom port 244. According to one embodiment, the vent hole 241 in thebase 240 is for venting air out of an air chamber and for receiving airinto the air chamber, as will become more evident. The insert to baseinterface 242 is for connecting an insert and the base 240. The housingto base interface is for connecting the housing 210 to the base 240. Thefemale threads 243 can be used for connecting the connector, forexample, with male threads associated with one end of a catheter. Thebottom port 244 can be used for delivering fluid to a patient or forreceiving fluid from a patient, for example, through a catheter.

FIG. 2D depicts an insert 260, according to one embodiment. For example,the insert 260 as depicted includes a housing to insert interface 261, alower valve chamber 262, a base to insert interface 263, and a vent hole264. The housing to insert interface 261 is for connecting the housing210 to the insert 260. The base to insert interface 263 can be used forconnecting the base 240 and the insert 260. The lower valve chamber 262,according to one embodiment, provides a volume that the lower portion ofthe valve plug 220 can reside when the connector is assembled. The venthole 264 is for venting air out of the air chamber and for receiving airinto the air chamber. According to one embodiment, the base 240's venthole 241 and the insert 260's vent hole 264 are aligned with each otherin order to vent air out of the air chamber and to receive air into theair chamber.

Referring to FIGS. 2A, 2C and 2D respectively, the housing 210, the base240 and the insert 260 can be made from a substantially rigid material,such as but not limited to, polycarbonate, polyvinyl chloride (PVC),acrylonitrile butadiene styrene (ABS) or plastic. Referring to FIG. 2B,the valve plug 220 can be made of a deformable material such as, but notlimited to, silicon, injection molded silicon or rubber.

As will become more evident, the housing 210, valve plug 220, base 240and insert 260 (FIGS. 2A, 2C and 2D respectively) can be assembled tocreate a connector 100 (FIGS. 1A-1C). For example, the base 240 (FIG.2C) and the insert 260 (FIG. 2D) can be connected at their respectivebase to insert interfaces 242, 263. The valve plug 220 can be placed inthe lower valve chamber 262 of the insert 260 and the housing 210 can beplaced over the valve plug 220 and a portion of the insert 260. Thehousing 210 and the insert 260 can be connected at their respectivehousing to insert interfaces 215, 261.

According to one embodiment, the various interfaces 215, 261, 217, 245,242. 263, such as the respective housing to insert interfaces 215, 261,the housing to base interfaces 217, 245 and the base to insertinterfaces 242, 263, provide for connecting respective componentstogether. The respective components can be clamped together at theinterfaces 215, 261, 217, 245, 242, 263, ultrasonically welded, orglued, among other things. An interface 215, 261, 217, 245, 242, 263that provides for clamping, according to one embodiment, includes a“clamping area” According to one embodiment, the housing 210 and theinsert 260 are press fitted together at the housing to base interfaces217, 245. According to one embodiment, the interfaces are connected in amanner that the outer surface of the connector is smooth, and,therefore, swabable. For example, in the case of ultrasonic welding,weld points can be provided on the inside of the connector.

FIG. 3 depicts a side cross section view of a partially assembledconnector 300, according to one embodiment. The partially assembledconnector 300 includes a valve plug 220, an insert 260, the housing toinsert interface 261, the top diaphragm 226 a, the lower valve chamber262, the bottom diaphragm 226 b, the vent hole 264 in the insert 260,the base to insert interface 263, an insert to top diaphragm interface302, an insert to bottom diaphragm interface 304, and a portion 306 ofthe fluid flow path 112.

As depicted in FIG. 3, the lower portion of the valve plug 220 has beeninserted into the lower valve chamber 262 provided by the insert 260.The insert to top diaphragm interface 302, and the insert to bottomdiaphragm interface 304 that can be used for fitting the valve plug 220in the connector 300. According to one embodiment, the top diaphragm 226a's expansion 227 a is fit snuggly between the insert 260 and thehousing 210 (FIG. 2A) at the respective housing to insert interlaces215, 261 when the housing 210 is placed over the insert 260. Accordingto one embodiment, the insert 260 and the housing 210 (FIG. 2A) providesrespective notches that conform respectively to the top and bottomdiaphragm's 226 a, 226 b expansions 227 a, 227 b. According to oneembodiment, the notches provide a tight fit for the expansions 227 a,227 b.

FIG. 4 depicts a top cross section view 400 of the outline of anassembled connector, according to one embodiment. FIG. 4 also depictsribs 402 and cross section line B of the connector that will be used fordepicting side cross section views of the assembled connector. Crosssection line B runs through at least one rib 402. FIG. 5 depicts a sidecross section view of an empty assembled connector from cross sectionline B, according to one embodiment. FIG. 6 depicts a side cross sectionview of an assembled connector that contains fluid from cross sectionline B, according to one embodiment. According to one embodiment, aportion of the fluid flow path runs through one or more ribs 402.

FIGS. 5-7 depict side cross section views of a connector 100 in greyscale, according to various embodiments, where the housing 210 is thedarkest shade of grey, the valve plug 220 and the base 240 are in anintermediate shade of grey, and the insert 260 is in the lightest shadeof grey.

FIG. 5 depicts a side cross section view of an empty unactuatedconnector through the cross section line B, which runs through at leastone rib, according to one embodiment. The depicted connector 100includes a housing 210, a valve plug 220, an insert 260 and a base 240.The depicted connector 100 also includes a housing top 212, top port211, valve plug top 290, fluid flow path 112, portion 507 of the fluidflow path 112, housing to insert interfaces 215, 261, insert to topdiaphragm interface 302, insert to bottom diaphragm interface 304, baseto insert interfaces 242, 263, portion 508 of fluid flow path 112,bottom port 244, a top seal 501, a shoulder seal 502, the housing innerwall 504 and an air chamber 110.

The assembled connector 100 provides seals 501, 502, according to oneembodiment. For example, the assembled connector 100 provides a top seal501 where the valve plug top 290 interfaces with the housing top 212.According to one embodiment, the interface between the valve plug top290 and the housing top 212 is a smooth surface that is swabable. Inanother example, the assembled connector 100 provides a shoulder seal502 where the valve plug 220's shoulder 224 interfaces with an innerwall 504 of the housing 210.

The top diaphragm 226 a's expansion 227 a is sandwiched between theinsert 260 and the housing 210 at the housing to insert interfaces 215,261, according to one embodiment. The bottom diaphragm 226 b's expansion227 b is fit snuggly, according to one embodiment, at the insert tobottom diaphragm interfaces 304. For example, the expansion 227 b can befit into notches associated with the insert 260 at the insert to bottomdiaphragm interfaces 304.

FIG. 5 also depicts portions 507, 508 of the fluid flow path 112 and theair chamber 110 that are separated at least in part by the valve plug220. The air chamber 110 is provided by, among other things, the lowersurface of the top diaphragm 226 a, the upper surface of the bottomdiaphragm 226 b, and the inner walls of the insert 260, according to oneembodiment.

The valve plug 220, according to one embodiment, can be deformed orcompressed when an actuator is inserted into the top port 211. Asdepicted in FIG. 5, the valve plug 220 is not deformed and notcompressed because an actuator is not inserted.

FIG. 6 depicts a side cross section view of an unactuated connector thatcontains fluid through cross section line B, which runs through at leastone rib, according to one embodiment. According to one embodiment, oneof the ribs 402 provides a portion 602 of the fluid flow path 112,according to one embodiment. As shown, FIG. 6 depicts a connector 100that includes a portion 507 of the fluid flow path 112, a rib 402,diaphragms 226 a, 226 b, insert 260, air chamber 110, vent holes 264,241, base 240, housing 210, valve plug 220, fluid flow path 112, portion602 of the fluid flow path 112, and portion 508 of fluid flow path 112.

FIG. 6 further depicts how the two diaphragms 226 a, 226 b can be usedto separate the fluid flow path 112 from the air chamber 110, accordingto one embodiment. For example, the air chamber 110 is formed, at leastin part, by the inner walls of the insert 260, the lower surface of thetop diaphragm 226 a, the outer surfaces of the valve plug's tail 229,and the upper surface of the bottom diaphragm 226 b. The fluid flow path112 is formed, at least in part, by portions of the housing 210, theinsert 260, the base 240, and the valve plug 220, More specifically, asdepicted, the fluid flow path 112 is formed, at least in part, by theinner walls of the upper portion of the housing 210 around the throat222 of the valve plug 220, the inner walls of the housing 210 around thevalve plug 220's shoulder 224 and the upper surface of the top diaphragm226 a, one of the housing 210's ribs 402, a lower region of the insert260 near the bottom diaphragm 226 b, the lower surface of the bottomdiaphragm 226 b, and the bottom port 244 of the base 240. The fluid flowpath 112 is separated from the air chamber 110, at least in part, by theupper surface of the top diaphragm 226 a and the lower surface of thebottom diaphragm 226 b.

FIG. 7 depicts a side cross section view of an actuated connector 100,according to one embodiment. FIG. 7 further depicts an actuator 701, ahousing 210, a valve plug 220, the base 240, the fluid flow path 112,the insert 260, the air chamber 110, a rib 402, the top port 211, thediaphragms 226 a, 226 b, the vent holes 264, 241, and bottom port 244.

As depicted in FIG. 7, an actuator 701 is inserted into the connector100 the connector 100 through the top port 211 for delivering fluid orreceiving fluid, according to one embodiment, For example, when thevalve plug 220 is deformed upon actuation, the fluid flow path 112 opensbetween the top port 211 and the bottom port 244, as depicted in FIG. 7.

More specifically, as depicted, the valve plug 220's tail 229 compresses(also known as “deforms”), the two diaphragms 226 a, 226 b stretchdownward, and the valve plug top 290 and shoulder 224 move downward.When the valve's top 290 and shoulder 224 move downward, the seals 501,502 depicted in the unactuated connector on FIGS. 5 and 6 are opened upproviding a fluid flow path 112 that is open between the top port 211and the bottom port 244 as depicted in FIG. 7. A fluid flow path 112that is open between the top port 211 and the bottom port 244 shall alsobe referred to herein as “an open fluid flow path.” The air chamber 110and the fluid flow path 112 are still separated at least in part by thedual diaphragm 226 a, 226 b upon actuation, according to one embodiment.

According to one embodiment, the fluid flow path 112 is not required togo through the valve plug 220 but instead can go around the valve plug220 as depicted in FIG. 7. For example, upon actuation, the single fluidflow path 112 enables fluid that flows from the tip of the actuator 701to interact, at least in part, with the valve plug top 290, the valveplug 220's shoulder 224, the upper surface of the top diaphragm 226 a,the inner walls of one of the ribs 402, the underneath surface of thebottom diaphragm 226 b and the inner walls of the bottom port 244,according to one embodiment. Similarly, if fluid were being drawn from apatient, the fluid would flow in the opposite direction, according toone embodiment.

According to one embodiment, an assembled connector 100 as depicted inFIGS. 1A-1D and FIGS. 5-7 is approximately 1.25 inches long andapproximately 0.4 inches in diameter. According to one embodiment, thelength of an assembled connector 100 can range from approximately 1 inchto 2 inches and the diameter of an assembled connector 100 can rangefrom approximately 0.4 inch to 1 inch. The width of the walls associatedwith the connector's components, such as the housing 210, the base 240,and the insert 260, among others, can vary, according to one embodiment.For example, the walls of the components can be made thicker ornarrower. According to one embodiment, the thickness of the walls of thecomponents can be varied as a part of providing minimal displacement.

As discussed herein, displacement of fluid typically occurs when aconnector includes moving parts, such as a valve plug. With positivedisplacement, an overdose can occur due medication being pushed into thepatient. However, according to various embodiments, minimal positivedisplacement is provided at least in part by the dual diaphragm. Forexample, the volumes associated with the connector, such as the fluidflow path and the air chamber, are small, according to one embodiment.Further, the dual diaphragm takes up space inside of the connectorresulting in less space for fluids and air, according to one embodiment.

Further, the movements of the two diaphragms' counteract each other,according to one embodiment. For example, referring to FIG. 1E3, uponactuation, both of the diaphragms 116, 118 move downwards. The movementof the top diaphragm 116 enlarges the fluid flow path's 112 volume whilethe movement of the bottom diaphragm 118 downwards decreases the fluidflow path's 112 volume. The top diaphragm's 116 movement downwardincreases the fluid flow path's 112 volume while the bottom diaphragm's118 movement downward decreases the fluid flow path's 112 volume, whichreduces the net volume change in comparison to a connector that does notprovide the counter balancing between two diaphragms 116, 118 on a fluidflow path 112's volume. Further, the top diaphragm 116 moves downwardsmore than the bottom diaphragm 118 does which results in the fluid flowpath's 112 volume enlarging and the air chamber's 110 volume decreasing.

By using two diaphragms 116, 118 where one increases the fluid flowpath's 112 volume and the other decreases the fluid flow path's 112volume, according to one embodiment, a smaller net volume change incomparison to a connector that does not use a diaphragm or that usesonly one diaphragm. For example, a valve plug 104 that included twodiaphragms 116, 118 could replace more space than a valve plug thatincluded no diaphragm or only one diaphragm. Thus, minimal negativedisplacement is provided upon actuation, at least in part, by the spacethat the valve plug 104 occupies and the counter balancing movements ofthe two diaphragms 116, 118, according to one embodiment.

As can be seen, according to one embodiment, minimal positivedisplacement can also be provided due to the relative sizes between thevalve plug 104, the volumes associated with the fluid flow path 112 andthe air chamber 110, and the counter balancing of the two diaphragms116, 118, among other things. More specifically, referring to FIG. 1C,when the actuator is removed from the connector 100, both diaphragms116, 118 move upwards. The movement of the top diaphragm 116 upwardsreduces the fluid flow path's 112 volume while the movement of thebottom diaphragm 118 upwards increases the fluid flow path's 112 volume.The top diaphragm's 116 movement upwards, which decreases the fluid flowpath's 112 volume, while the bottom diaphragm's 118 movement upwards,which increases the fluid flow path's 112 volume, reduces the net volumechange in comparison to a connector that does not provide counterbalancing of two diaphragms on a fluid flow path's volume.

Therefore, according to various embodiments, the counter balancingeffects of the movements of the two diaphragms 116, 118 on the fluidflow path's 112 volume provides, at least in part, for minimaldisplacement.

Further, referring to FIGS. 1A-1C, it is the changes in the respectivevolumes of the fluid flow path 112 and the air chamber 110 due at leastin part to the movement of the diaphragms 116, 118 that provide forpositive displacement 132 upon disconnection and negative displacement128 upon actuation, according to one embodiment.

For example, referring to FIG. 1B, upon actuation, the top diaphragm 116moves downwards more than the bottom diaphragm 118 does which results inthe fluid flow path's 112 volume increasing and the air chamber's 110volume decreasing. Increasing the fluid flow path's 112 volume whiledecreasing the air chamber's 110 volume provides for negativedisplacement 128, according to one embodiment. Thus, minimal negativedisplacement is provided upon actuation, at least in part, by the spacethat the valve plug 104 occupies or the counter balancing movements ofthe two diaphragms 116, 118, or a combination thereof, according to oneembodiment.

Further, referring to FIG. 1C, upon disconnection, the top diaphragm 116moves upwards more than the bottom diaphragm 118 does which results inthe fluid flow path's 112 volume decreasing and the air chamber's 110volume increasing. Decreasing the fluid flow path's 112 volume whileincreasing the air chamber's 110 volume provides for positivedisplacement, according to one embodiment. Thus, minimal positivedisplacement is provided upon disconnection, at least in part, by thespace that the valve plug 104 occupies and the counter balancingmovements of the two diaphragms 116, 118, according to one embodiment.

Back pressure on a connector occurs when a patient coughs, regurgitates,or their blood pressure spikes, among other things. Referring to FIG. 5,back pressure applies pressure on the underneath surface of the bottomdiaphragm 226 b, Fluid interacts with the top surface of the topdiaphragm 226 a and the underneath surface of the bottom diaphragm 226b. Since the surface area of the bottom diaphragm 226 b that isinteracting with fluid is larger than the surface area of the topdiaphragm 226 a that is interacting with fluid, according to oneembodiment, there will be more force upwards than downwards, which willcause the valve plug 220 to push upwards. For example, when the valveplug 220 is pushed upwards due to back pressure and the larger surfacearea of the bottom diaphragm 226 b interacting with fluid, the seals501, 502 at the shoulder and at the top of the valve plug 220 becomestronger. Therefore, according to one embodiment, a slit in a valve plugthat enables the valve plug to expand is not required to prevent fluidsfrom leaking during back pressure.

FIGS. 8A and 83 depict a flowchart for a method of creating a connector,according to one embodiment. The description of flowchart 800 shallrefer to FIGS. 5, 6 and 7.

At 810, the method begins.

At 820, referring to FIGS. 5 and 6, a connector assembly is created.

For example, at 822, an insert 260 is securely connected with a base240, for example, at the base to insert interfaces 242, 263. Variousmethods can be used for securely connecting the insert 260 to the base240, such as, ultrasonic welding, clamping, gluing, screwing componentstogether, among other things. The base 240 includes a bottom port 244.An air chamber 110 is provided, at least in part, by the insert 260.

At 824, a valve plug 220 is inserted into the insert 260. The valve plug220 includes two diaphragms 226 a, 226 b.

At 826, a housing 210 is placed over the valve plug 220 and the insert260. The housing 210 includes a top port 211. A single fluid flow path112 flows between the bottom port 244 and the top port 211, and the twodiaphragms 226 a, 226 b separate the air chamber 110 and the singlefluid flow path 112.

At 828, the housing 210 is securely connected with the base 240, forexample, at the housing to base interface 217, 245. Various methods canbe used for securely connecting the housing 210 and the base 240, suchas, ultrasonic welding, clamping, gluing, screwing components together,among other things.

At 830, referring to FIG. 1C, the connector assembly is configured toprovide positive displacement 132 due to a volume associated with thesingle fluid flow path 112 decreasing and a volume associated with theair chamber 110 increasing when the valve plug 220 returns to anundeformed state by removing an actuator from the top port 211.

For example, as discussed herein, the two diaphragms 116, 118counteracting each other upon disconnection providing for positivedisplacement 132. More specifically, according to one embodiment, theair chamber 110 is formed, at least in part, by the inner walls of theinsert 260, the lower surface of the top diaphragm 226 a, the outersurfaces of the valve plug's tail 229, and the upper surface of thebottom diaphragm 226 b. Further, the fluid flow path 112 is formed, atleast in part, by the inner walls of the upper portion of the housing210 around the throat 222 of the valve plug 220, the inner walls of thehousing 210 around the valve plug 220's shoulder 224 and the uppersurface of the top diaphragm 226 a, one of the housing 210's ribs 402, alower region of the insert 260 near the bottom diaphragm 226 b, thelower surface of the bottom diaphragm 2261), and the bottom port 244 ofthe base 240, according to one embodiment.

The top diaphragm 226 a moves upwards more than the bottom diaphragm 226b does which results in the fluid flow paths 112 volume decreasing andthe air chamber's 110 volume increasing, according to one embodiment.Decreasing the fluid flow path's 112 volume while increasing the airchamber's 110 volume provides for positive displacement, according toone embodiment. Therefore, according to one embodiment, it is thechanges in the respective volumes of the fluid flow path 112 and the airchamber 110 due, at least in part, to the movement of the diaphragms 226a, 226 b that provide for positive displacement upon disconnection.

At 840, the process ends.

FIG. 9 is a flow chart for a method of making a connector, according toanother embodiment.

At 910, the method begins.

At 920, a single fluid flow path 112 is associated with the connector100. The single fluid flow path 112 is configured for delivering fluidto a person and configured for receiving fluid from a person. Forexample, referring to FIGS. 1B and 5, the fluid flow path 112 is formed,at least in part, by inner walls of an upper portion of the housing 210around a throat 222 of the valve plug 220, inner walls of the housing210 around a shoulder 224 of the valve plug 220, the upper surface of afirst 226 a of the two diaphragms, a rib 402 of the housing 210, a lowerregion of the insert 260 near a second 226 b of the two diaphragms, thelower surface of the second diaphragm 226 b, and a bottom port 244 ofthe base 240, according to one embodiment.

At 930, an air chamber 110 is associated with the connector 100.Referring to FIG. 13, the air chamber 110 is configured for expellingair from the air chamber 110 when an actuator 124 is inserted into theconnector 100 and, referring to FIG. 1C, for receiving air into the airchamber 110 when the actuator 124 is removed from the connector 100. Forexample, referring to FIGS. 2B and 5, the air chamber 110 is formed, atleast in part, by the inner walls of the insert 260, the lower surfaceof a first 226 a of the two diaphragms, the outer surface of a tail 229of the valve plug 220, and the upper surface of a second 226 b of thetwo diaphragms, according to one embodiment.

At 940, a valve plug 104 that includes two diaphragms 116, 118 isassociated with the connector 100. Referring to FIG. 1C, the connector100 provides positive displacement 132, at least in part, due to avolume associated with the single fluid flow path 112 decreasing and avolume associated with the air chamber 110 increasing, returning thevalve plug 104 and the two diaphragms 116, 118 to an undeformed anduncompressed state upon removal of an actuator from the connector 100.

At 950, the method ends.

According to another embodiment, the connector is configured to providenegative displacement due to a volume associated with the air chamber110 decreasing and a volume associated with the single fluid flow path112 increasing, as discussed herein.

Further, as discussed herein, minimal positive displacement can beprovided, at least in part, by the movements of the two diaphragms 116,118 counteract each other or the space that the valve plug 104 occupies,or a combination thereof, according to various embodiments.

According to one embodiment, the methods 800, 900 of making a connector100, as depicted in FIGS. 8A, 8B and 9, provide a connector 100 asdepicted in FIGS. 1A-7. For example, referring to FIGS. 1A-1C, either ofthe methods 800, 900 (FIGS. 8A, 8B, and 9) for making a connector 100provide a connector 100 comprising a single fluid flow path 112, an airchamber 110 and a valve plug 104 where the single fluid flow path 112 isconfigured for delivering fluid to a person and configured for receivingfluid from a person, the air chamber 110 is configured for expelling airfrom the air chamber 110 when an actuator 124 is inserted into theconnector 100 and for receiving air into the chamber 110 when theactuator 124 is removed from the connector 100, and the valve plug 104comprising two diaphragms 116, 118 that separate the air chamber 110from the single fluid flow path 112, wherein valve plug 104 isconfigured for creating positive displacement 132 (FIG. 1C) by returningthe valve plug 104 to its uncompressed state when the actuator 124 isremoved from the connector 100.

In a second example, referring to FIGS. 5 and 6, either of the methods800, 900 (FIGS. 8A, 8B, and 9) for making a connector 100 provide aconnector 100 that includes a housing 210, a base, 240, insert 260 and avalve plug 220. The housing 210 includes a top port 211. The base 240includes a bottom port 244. The housing 210 is securely connected to thebase 240. The insert 260 is securely connected to the base 240. Theinsert 260 is inside a portion of the housing 210. The single fluid flowpath 112 is inside a portion of the housing 210. The valve plug 220includes two diaphragms 226 a, 226 b. The valve plug 220 is inside avolume formed by portions of the insert 260 and the housing 210. Theconnector 100 is configured to provide positive displacement when thevalve plug 220 returns to an undeformed state upon removal of anactuator from the top port 211.

Example embodiments of the subject matter are thus described. Althoughthe subject matter has been described in a language specific tostructural features and/or methodological acts, it is to be understoodthat the subject matter defined in the appended claims is notnecessarily limited to the specific features or acts described above.Rather, the specific features and acts described above are disclosed asexample forms of implementing the claims.

Various embodiments have been described in various combinations andillustrations. However, any two or more embodiments or features may becombined. Further, any embodiment or feature may be used separately fromany other embodiment or feature. Phrases, such as “an embodiment,’ “oneembodiment,” among others, used herein, are not necessarily referring tothe same embodiment. Features, structures, or characteristics of anyembodiment may be combined in any suitable manner with one or more otherfeatures, structures, or characteristics.

What is claimed is:
 1. A connector for providing positive displacementupon disconnection, the connector comprising (i) a housing having an airpassage and an insert, wherein a single fluid flow path is formedbetween an inner surface of a housing and an outer surface of an insert,and (ii) a valve plug comprising a top diaphragm and a bottom diaphragm,wherein the top and bottom diaphragms and an inner surface of the insertseparate an air chamber from the fluid flow path, wherein the airpassage is configured to permit ventilation of the air chamber.
 2. Theconnector of claim 1, wherein upon actuation of the connector byinsertion of an actuator, the top and bottom diaphragms shift tominimize a net volume change in the flow path.
 3. The connector of claim1, wherein the top and bottom diaphragms are configured to createpositive displacement by returning the valve plug to its uncompressedstate when an actuator is removed from the connector.
 4. The connectorof claim 1, wherein changes in respective volumes of the fluid flow pathand the air chamber due, at least in part, to respective movements ofthe top and bottom diaphragms provide for positive displacement when anactuator is removed from the connector and provide for negativedisplacement by compressing the valve plug when the actuator is insertedinto the connector.
 5. The connector of claim 1, wherein upon return ofthe valve plug to an uncompressed state, the top diaphragm decreasesdimensions of the fluid flow path and the bottom diaphragm increasesdimensions of the fluid flow path such that a volume of the single fluidflow path decreases and a volume of the air chamber increases.
 6. Theconnector of claim 1, wherein upon compression of the valve plug, thetop diaphragm increases dimensions of the fluid flow path and the bottomdiaphragm decreases dimensions of the fluid flow path such that a volumeof the single fluid flow path increases and a volume of the air chamberdecreases.
 7. The connector of claim 1, wherein the top diaphragm has alarger diameter than the bottom diaphragm.
 8. The connector of claim 1,wherein the bottom diaphragm has a larger fluid surface area than thetop diaphragm, and wherein a fluid surface area is a surface area thatinteracts with fluid.
 9. The connector of claim 1, wherein the topdiaphragm shifts a greater distance than the bottom diaphragm when anactuator is inserted into the connector and when the actuator is removedfrom the connector.
 10. The connector of claim 1, wherein the airchamber is formed, at least in part, by a portion of the insert disposedbetween the top and bottom diaphragms.
 11. The connector of claim 10,wherein the air chamber is formed, at least in part, by the innersurface of the insert, a lower surface of the top diaphragm, an outersurface of a tail of the valve plug, and an upper surface of the bottomdiaphragm, when the tail extends between the lower surface of the topdiaphragm and the upper surface of the bottom diaphragm.
 12. A method ofcontrolling fluid flow through a fluid connector, the method comprising(i) providing a connector with a housing having an air passage, aninsert, and forming a single fluid flow path, through the connector,between an inner surface of a housing and an outer surface of an insert,and (ii) providing a valve plug, having a top diaphragm and a bottomdiaphragm, within the connector, wherein the top and bottom diaphragmsand an inner surface of the insert separate an air chamber from thefluid flow path, and ventilation of the air chamber is permitted throughthe passage.
 13. The method of claim 12, comprising actuating theconnector such that the connector, the top and bottom diaphragms shiftto minimize a net volume change in the single fluid flow path.
 14. Themethod of claim 12, wherein the connector provides negative displacementdue to a volume associated with the single fluid flow path increasingand a volume associated with the air chamber decreasing when the valveplug deforms upon insertion of an actuator into the connector.
 15. Themethod of claim 12, wherein upon return of the valve plug to anuncompressed state, the top diaphragm decreases dimensions of the fluidflow path and the bottom diaphragm increases dimensions of the fluidflow path such that a volume of the single fluid flow path decreases anda volume of the air chamber increases.
 16. The method of claim 12,wherein upon compression of the valve plug, the top diaphragm increasesdimensions of the fluid flow path and the bottom diaphragm decreasesdimensions of the fluid flow path such that a volume of the single fluidflow path increases and a volume of the air chamber decreases.
 17. Themethod of claim 12, wherein the top diaphragm has a larger diameter thanthe bottom diaphragm.
 18. The method of claim 12, wherein the topdiaphragm shifts a greater distance than the bottom diaphragm when anactuator is inserted into the connector and when the actuator is removedfrom the connector.
 19. The method of claim 12, further comprising thestep of providing the insert between the top and bottom diaphragms,wherein the air chamber is provided at least in part a portion of theinsert disposed between the top and bottom diaphragms.
 20. The method ofclaim 19, wherein the air chamber is formed, at least in part, by theinner surface of the insert, a lower surface of the top diaphragm, anouter surface of a tail of the valve plug, and an upper surface of thebottom diaphragm, when the tail extends between the lower surface of thetop diaphragm and the upper surface of the bottom diaphragm.